Robot apparatus

ABSTRACT

The invention proposes a robot apparatus capable of autonomously performing actions in natural ways. The robot apparatus includes a control unit having emotion/-instinct models linked to the actions and deciding a next action by changing the emotion/instinct models based on the input information. A robot apparatus can be realized which autonomously behaves in accordance with the emotional and instinctive states created in itself, and hence which autonomously behaves in a natural way.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a robot apparatus, and moreparticularly it is suitably applied to a pet robot performing actionslike, for example, a four-footed animal.

2. Description of the Related Art

Heretofore, a four-footed walking pet robot has been proposed anddeveloped which performs actions in predetermined ways in response tocommands from a user or depending on ambient environments. Such a petrobot resembles in shape to a four-footed animal often kept in thehouse, such as a dog or cat. A dog-like pet robot, for example, isdesigned to always take a lying-down posture upon receiving a command“lie down” from the user, or to always give a “hand” (front leg) whenthe user stretches the hand to just under the robot nose.

However, such a conventional pet robot performs actions only inpredetermined ways in accordance with commands from the user or ambientenvironments, and it cannot be said as a autonomous robot capable ofdeciding an action by itself. In other words, the conventional pet robotdoes not behave as with a genuine pet, and hence has a difficulty infully satisfying such a user's demand as obtaining a pet robot as closeas possible to a genuine pet.

SUMMARY OF THE INVENTION

In view of the state of art set forth above, an object of the presentinvention is to propose a robot apparatus capable of autonomouslyperforming actions in natural ways.

To achieve the above object, the present invention provides a robotapparatus performing actions in accordance with input informationsupplied to the robot apparatus, wherein the robot apparatus includes anemotion/instinct model changing unit having emotion/-instinct modelslinked to the actions and deciding a next action by changing theemotion/instinct models based on the input information.

Since the robot apparatus includes the emotion/-instinct models linkedto the actions and decides the next action by changing theemotion/instinct models based on the input information, the robotapparatus can autonomously behave in accordance with the emotional andinstinctive states created in itself.

Also, the present invention provides a robot apparatus performingactions in accordance with input information supplied to the robotapparatus, wherein the robot apparatus includes an operating statedeciding unit for deciding a next operating state subsequent to acurrent operating state based on both the current operating statedepending on a history of the input information having been supplied insuccession and the input information supplied next.

Since the next operating state subsequent to the current operating stateis decided based on both the current operating state depending on ahistory of the input information having been supplied in succession andthe input information supplied next, the robot apparatus canautonomously behave in accordance with the emotional and instinctivestates created in itself.

Further, the present invention provides a robot apparatus takingpostures decided based on physical configurations and mechanisms andtransiting the postures in accordance with input information, whereinthe robot apparatus includes a posture transition unit for changing acurrent posture of the robot apparatus for transition from the currentposture to a posture corresponding to the input information via apredetermined route.

Since the current posture of the robot apparatus is changed fortransition from the current posture to the posture corresponding to theinput information via the predetermined route, the robot apparatus canbe avoided from being forced to take an impossible posture or fromturning over.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic view showing one embodiment of a pet robotaccording to the present invention;

FIG. 2 is a block diagram showing a circuit configuration of the petrobot;

FIG. 3 is a block diagram showing data processing in a controller;

FIG. 4 is a diagram showing data processing executed by anemotion/instinct model unit;

FIG. 5 is a diagram showing data processing executed by theemotion/instinct model unit;

FIG. 6 is a diagram showing data processing executed by theemotion/instinct model unit;

FIG. 7 is a state transition diagram of a finite automaton in an actiondeciding mechanism; and

FIG. 8 is a posture transition diagram for a posture deciding mechanism.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

One embodiment of the present invention will be described below indetail with reference to the drawings.

(1) Construction of Pet Robot

Referring to FIG. 1, numeral 1 denotes the entirety of a pet robotcomprising a head portion 2 corresponding to the head, a body portion 3corresponding to the body, leg portions 4A-4D corresponding to legs, anda tail portion 5 corresponding to a tail, these components being coupledinto the form close to a pet. The head portion 2, the leg portions 4A-4Dand the tail portion 5 are moved relative to the body portion 3 so thatthe pet robot behaves like a genuine four-footed animal.

The head portion 2 includes an image recognizing unit 10 whichcorresponds to eyes and comprises, e.g., a CCD (Charge Coupled Device)camera for picking up an image, a microphone 11 which correspond to anear and receives a voice, and a speaker 12 which correspond to a mouthand generates a voice, these components being attached to respectivepredetermined positions of the head portion 2. The head portion 2further includes a remote-controller command receiver 13 for receivingcommands transmitted from a user via a remote controller (not shown), atouch sensor 14 for detecting a contact of the user's hand upon the headportion, and an image display unit 15 for displaying an image producedinside the pet robot 1.

The body portion 3 includes a battery 21 attached to a positioncorresponding to the belly, and an electronic circuit (not shown), etc.which are installed within the body portion 3 for controlling the entireoperation of the pet robot 1.

Actuators 23A-23N are provided respectively at articulations of the legs4A-4D, joints between the legs 4A-4D and the body portion 3, a jointbetween the body portion 3 and the head portion 2, a joint between thebody portion 3 and the tail portion 5, etc. The actuators.23A-23N aredriven under control of the electronic circuit installed within the bodyportion 3. The pet robot 1 is able to behave like a genuine four-footedanimal by driving the actuators 23A-23N in such manners that the headportion 2 swings vertically or horizontally, it wags the tail portion 5,and the legs 4A-4D are moved to make the pet robot walk or run.

(2) Circuit Configuration of Pet Robot

The circuit configuration of the pet robot 1 will now be described withreference to FIG. 2. The head portion 2 includes a command receivingunit 30 which is made up of the microphone 11 and the remote-controllercommand receiver 13, an external sensor 31 which is made up of the imagerecognizing unit 10 and the touch sensor 14, the speaker 12, and theimage display unit 15. The body portion 3 includes the battery 21attached to its lower surface, and also includes therein a controller 32for controlling the entire operation of the pet robot 1 and an internalsensor 35 which is made up of a battery sensor 33 for detecting theremaining charge of the battery 21 and a heat sensor 34 for detectingthe heat generated inside the pet robot 1. Further, the actuators23A-23N are provided in the predetermined positions of the pet robot 1.

The command receiving unit 30 receives commands, such as “walk”, “liedown” and “run after a ball”, given from the user to the pet robot 1,and it is made up of the remote-controller command receiver 13 and themicrophone 11. When a desired command is inputted to the remotecontroller (not shown) upon manipulation of the user, the remotecontroller transmits an infrared ray depending on the inputted commandto the remote-controller command receiver 13. Upon receiving theinfrared ray, the remote-controller command receiver 13 produces areception signal S1A and transmits it to the controller 32. When theuser utters a voice depending on the desired command, each microphone 11receives the voice uttered from the user, produces a voice signal S1B,and then transmits it to the controller 32. Thus, the command receivingunit 30 produces command signals S1, i.e., the reception signal S1A andthe voice signal S1B, in accordance with commands given to the pet robot1 from the user, followed by supplying the command signals S1 to thecontroller 32.

The touch sensor 14 in the external sensor 31 detects actions, such as“stroking” and “striking”, applied to the pet robot 1 from the user.When the user performs a desired action by touching the touch sensor 14,the touch sensor 14 produces a contact detection signal S2A depending onthe applied action and transmits it to the controller 32.

The image recognizing unit 10 in the external sensor 31 recognizes theambient environment of the pet robot 1, and detects information of theambient environment such as “dark” and “there is a favorite toy”, ormotions of other pet robots such as “another pet robot is running”. Tothis end, the image recognizing unit 10 picks up an image ofsurroundings of the pet robot 1 and transmits a resulting image signalS2B to the controller 32. Thus, the external sensor 31 produces externalinformation signals S2, i.e., the contact detection signal S2A and theimage signal S2B in accordance with external information given from theexterior of the pet robot 1, followed by supplying the externalinformation signals S2 to the controller 32.

The internal sensor 35 detects the inner status of the pet robot 1itself, such as “hungry” meaning that the battery charge is low, and“feverish”. To this end, the internal sensor 35 is made up of thebattery sensor 33 and the heat sensor 34.

The battery sensor 33 detects the remaining charge of the battery 21 forsupplying power to various circuits in the pet robot 1, and transmits aresulting battery-charge detection signal S3A to the controller 32. Theheat sensor 34 detects the heat generated inside the pet robot 1, andtransmits a resulting heat detection signal S3B to the controller 32.Thus, the internal sensor 35 produces internal information signals S3,i.e., the battery-charge detection signal S3A and the heat detectionsignal S3B, in accordance with information on the interior of the petrobot 1, followed by supplying the internal information signals S3 tothe controller 32.

The controller 32 produces control signals S5A-S5N for driving theactuators 23A-23N based on the command signals S1 supplied from thecommand receiving unit 30, the external information signals S2 suppliedfrom the external sensor 31, and the internal information signals S3supplied from the internal sensor 35. The control signals S5A-S5N aretransmitted respectively to the actuators 23A-23N for driving them,whereupon the pet robot 1 is operated.

On that occasion, the controller 32 produces, as required, a voicesignal S10 and an image signal S11 which are outputted to the exterior.The voice signal S10 is outputted to the exterior via the speaker 12,and the image signal S11 is transmitted to the image display unit 15 todisplay a desired image, thereby providing necessary information to theuser.

(3) Data Processing in Controller

The data processing in the controller 32 will now be described. Thecontroller 32 executes software data processing of the command signalsS1 supplied from the command receiving unit 30, the external informationsignals S2 supplied from the external sensor 31, and the internalinformation signals S3 supplied from the internal sensor 35 inaccordance with a program previously stored in a predetermined memoryarea. Resulting control signals S5 are supplied to the actuators 23.

As shown in FIG. 3, details of the data processing in the controller 32are functionally divided into an emotion/instinct model unit 40 as ameans for changing an emotion/instinct model, an action decidingmechanism 41 as a means for deciding an operating state, a posturetransition mechanism 42 as a posture transition means, and a controlmechanism 43. The command signals S1 supplied from the exterior, theexternal information signals S2 and the internal information signals S3are applied to both the emotion/instinct model unit 40 and the actiondeciding mechanism 41.

As shown in FIG. 4, the emotion/instinct model unit 40 includes a group50 of basic emotions comprising emotion units 50A-50C which serve as aplurality of independent emotion models, and a group 51 of basic desirescomprising desire units 51A-51C which serve as a plurality ofindependent desire models. Of the group 50 of basic emotions, theemotion unit 50A represents “delight”, the emotion unit 50B represents“grief”, and the emotion unit 50C represents “anger”.

Each of the emotion units 50A-50C indicates a degree of the emotion withintensity varying from 0 to 100 levels, for example, and changes theintensity of the emotion from moment to moment in accordance with thecommand signals S1, the external information signals S2 and the internalinformation signals S3 supplied to them. Thus, the emotion/instinctmodel unit 40 represents time-dependent changes of the emotions in amodeling manner; namely, it expresses an emotional state of the petrobot 1 by combining the momentarily varying intensities of outputs fromthe emotion units 50A-50C with each other.

Of the group 51 of basic desires, the desire unit 51A represents“appetite”, the desire unit 51B represents “sleepiness”, and the desireunit 51C represents a “desire for exercise”. As with the emotion units50A-50C, each of the desire units 51A-51C indicates a degree of thedesire with intensity varying from 0 to 100 levels, for example, andchanges the intensity of the desire from moment to moment in accordancewith the command signals S1, the external information signals S2 and theinternal information signals S3 supplied to them. Thus, theemotion/instinct model unit 40 represents time-dependent changes of theinstinct desires in a modeling manner; namely, it expresses aninstinctive state of the pet robot 1 by combining the momentarilyvarying intensities of outputs from the desire units 51A-51C with eachother.

As described above, the emotion/instinct model unit 40 changes theintensities of respective outputs from the emotion units 50A-50C and thedesire units 51A-51C in accordance with input information S1-S3 given bythe command signals S1, the external information signals S2 and theinternal information signals S3. Then, the emotion/instinct model unit40 combines the varying intensities of outputs from the emotion units50A-50C with each other to decide the emotional state, and combines thevarying intensities of outputs from the desire units 51A-51C to decidethe instinctive state. The decided emotional and instinctive states aretransmitted as emotion/instinct state information S10 to the actiondeciding mechanism 41.

Further, the emotion/instinct model unit 40 couples desired ones of theemotion units in the group 50 of basic emotions with each other in amutually inhibiting or stimulating manner. When the intensity of outputfrom one of the coupled emotion units is changed, the intensity ofoutput from the other emotion unit is also changed correspondingly. Thiscontributes to realizing the pet robot 1 expressing natural emotions.

More specifically, as shown in FIG. 5, the emotion/-instinct model unit40 couples the “delight” emotion unit 50A and the “grief” emotion unit50B in a mutually inhibiting manner such that when the pet robot 1 ispraised by the user, the intensity of output from the “delight” emotionunit 50A is increased and the intensity of output from the “grief”emotion unit 50B is reduced correspondingly even though the inputinformation S1-S3 are not supplied which cause the intensity of outputfrom the “delight” emotion unit 50A to increase and the intensity ofoutput from the “grief” emotion unit 50B to be changed to reduce at thesame time. Also, with the emotion/instinct model unit 40 coupling boththe emotion units 50A and 50B, when the intensity of output from the“grief” emotion unit 50B is increased, the intensity of output from the“delight” emotion unit 50A is reduced correspondingly with an increasein the intensity of output from the “grief” emotion unit 50B.

Likewise, the emotion/instinct model unit 40 couples the “grief” emotionunit 50B and the “anger” emotion unit 50C in a mutually inhibitingmanner such that when the pet robot 1 is struck by the user, theintensity of output from the “anger” emotion unit 50C is increased andthe intensity of output from the “grief” emotion unit 50B is alsoincreased correspondingly even though the input information S1-S3 arenot supplied which cause the intensity of output from the “anger”emotion unit 50C to increase and the intensity of output from the“grief” emotion unit 50B to be changed to increase at the same time.Further, with the emotion/instinct model unit 40 coupling both theemotion units 50C and 50B, when the intensity of output from the “grief”emotion unit 50B is increased, the intensity of output from the “anger”emotion unit 50C is also increased correspondingly with an increase inthe intensity of output from the “grief” emotion unit 50B.

In addition, as with the above-described coupling between desired onesof the emotion units 50, the emotion/instinct model unit 40 couplesdesired ones of the desire units in the group 51 of basic desires witheach other in a mutually inhibiting or stimulating manner. When theintensity of output from one of the coupled desire units is changed, theintensity of output from the other desire unit is also changedcorrespondingly. This contributes to realizing the pet robot 1expressing natural instincts.

Returning to FIG. 3, the emotion/instinct model unit 40 is supplied withbehavior information S12 indicating the nature of current or past actionof the pet robot 1 itself, such as “it is walking for a long time”, fromthe action deciding mechanism 41 in the downstream stage. Depending onthe action of the pet robot 1 indicated by the behavior information S12,therefore, the emotion/-instinct model unit 40 produces differentcontents of the emotion/instinct state information S10 even with thesame input information S1-S3 applied.

Concretely, as shown in FIG. 6, the emotion/instinct model unit 40includes intensity increasing/reducing functions 55A-55C which aredisposed upstream of the emotion units 50A-50C, respectively, forincreasing and reducing the intensities of outputs from the emotionunits 50A-50C based on the behavior information S12 indicating theaction of the pet robot 1, as well as the input information S1-S3. Then,the intensities of outputs from the emotion units 50A-50C are increasedand reduced in accordance with intensity information S14A-S14C outputtedfrom the intensity increasing/reducing functions 55A-55C, respectively.

For example, when the pet robot 1 greets the user and the user strokesthe head of the pet robot 1, i.e., when the behavior information S12indicating “the pet robot 1 greets the user” and the input informationS1-S3 indicating “the user strokes the head of the pet robot 1” are bothapplied to the intensity increasing/reducing function 55A, theemotion/instinct model unit 40 increases the intensity of output fromthe “delight” emotion unit 50A. However, when the user strokes the headof the pet robot 1 while the pet robot 1 is doing some work or task,i.e., when the behavior information S12 indicating “the pet robot 1 isdoing some work” and the input information S1-S3 indicating “the userstrokes the head of the pet robot 1” are both applied to the intensityincreasing/-reducing function 55A, the emotion/instinct model unit 40does not change the intensity of output from the “delight” emotion unit50A.

Thus, the emotion/instinct model unit 40 decides the intensities ofrespective outputs from the emotion units 50A-50C while referring to notonly the input information S1-S3 but also the behavior information S12indicating the current or past action of the pet robot 1. Accordingly,for example, when the user strokes the head of the pet robot 1 out ofmischief while the pet robot 1 is doing some task, it is possible toprevent an increase in the intensity of output from the “delight”emotion unit 50A and to avoid the pet robot 1 from expressing unnaturalemotion of delight. Similarly, for the desire units 51A-51C, theemotion/instinct model unit 40 also increases and reduces theintensities of respective outputs from the desire units 51A-51C inaccordance with not only the input information S1-S3 but also thebehavior information S12 supplied thereto.

As described above, upon receiving the input information S1-S3 and thebehavior information S12, the intensity increasing/reducing functions55A-55C produce and output intensity information S14A-S14C depending onpreset parameters. By presetting the parameters to different values fromone pet robot to another, the pet robots can be given individualcharacteristics, e.g., one pet robot being irritable and another petrobot being cheerful.

Returning to FIG. 3, the action deciding mechanism 41 decides a nextaction based on input information S14 given by the command signals S1,the external information signals S2, the internal information signalsS3, the emotion/instinct state information S10, and the behaviorinformation S12, and then transmits the contents of the decided action,as action command information S16, to the posture transition mechanism42.

More specifically, as shown in FIG. 7, the action deciding mechanism 41employs an algorithm called a finite automaton 57 having a finite numberof states, wherein a history of the input information S14 supplied inthe past is represented by operating states (hereinafter referred to asStates), and the current State is transited to the next State based onboth the currently supplied input information S14 and the current State,thereby deciding the next action. Thus, the action deciding mechanism 41transits the State each time the input information S14 is supplied, anddecides the next action depending on the transited State; namely, itdecides the next action by referring to not only the current inputinformation S14 and the past input information S14.

Accordingly, for example, if the input information S14 indicating “theball has disappeared” is supplied when a State ST1 indicating “pet robotis running after a ball” is the current State, transition to a State ST5indicating “standing” follows. On the other hand, if the inputinformation S14 indicating “stand up” is supplied when a State ST2indicating “lying” is the current State, transition to a State ST4indicating “standing” follows. It is thus understood that the States ST4and ST5 indicate the same action, but differ from each other because ofa difference in history of the input information S14 in the past.

In practice, upon detecting a predetermined trigger, the action decidingmechanism 41 effects transition from the current State to the nextState. Concretely, a trigger is provided by, for example, the fact thata period of time during which the action in the current State continueshas reached a certain value, or that the particular input informationS14 is applied, or that the intensity of output from a desired one ofthe emotion units 50A-50C and the desire units 51A-51C whose outputintensities are represented by the emotion/instinct state informationS10 supplied from the emotion/instinct model unit 40 has exceeded apredetermined threshold.

On that occasion, based on whether the intensity of output from adesired one of the emotion units 50A-50C and the desire units 51A-51Cwhose output intensities are represented by the emotion/instinct stateinformation S10 supplied from the emotion/instinct model unit 40 hasexceeded the predetermined threshold, the action deciding mechanism 41selects the State to be transited. In other words, even with the samecommand signals S1 applied, for example, the action deciding mechanism41 effects transition to the different States depending on theintensities of outputs from the emotion units 50A-50C and the desireunits 51A-51C.

Accordingly, for example, upon detecting based on the externalinformation signals S2 that the user's hand is stretched to just underthe robot nose, detecting based on the emotion/instinct stateinformation S10 that the intensity of output from the “anger” emotionunit 50C is not greater than the predetermined threshold, and detectingbased on the internal information signals S3 that “the pet robot is nothungry”, i.e., that the battery voltage is not lower than apredetermined threshold, the action deciding mechanism 41 produces theaction command information S16 causing the pet robot to “give the hand”in response to the user's hand being stretched to just under the robotnose, and then transmits it to the posture transition mechanism 42.

Also, for example, upon detecting that the user's hand is stretched tojust under the robot nose, detecting that the intensity of output fromthe “anger” emotion unit 50C is not greater than the predeterminedthreshold, and detecting that “the pet robot is hungry”, i.e., that thebattery voltage is lower than the predetermined threshold, the actiondeciding mechanism 41 produces the action command information S16causing the pet robot to “lick the user's hand”, and then transmits itto the posture transition mechanism 42.

Further, for example, upon detecting that the user's hand is stretchedto just under the robot nose, and detecting that the intensity of outputfrom the “anger” emotion unit 50C is greater than the predeterminedthreshold, the action deciding mechanism 41 produces the action commandinformation S16 causing the pet robot to “turn the head sideways in ahuff” regardless of whether “the pet robot is not hungry”, i.e., whetherthe battery voltage is not lower than the predetermined threshold, andthen transmits the action command information S16 to the posturetransition mechanism 42.

Moreover, in accordance with the intensity of output from a desired oneof the emotion units 50A-50C and the desire units 51A-51C whose outputintensities are represented by the emotion/instinct state informationS10 supplied from the emotion/instinct model unit 40, the actiondeciding mechanism 41 decides the magnitude of one or more parametersfor the action performed in the transited State, e.g., the speed ofwalking, the stroke and speed of motions of the hand and legs, and thepitch and loudness of sounds uttered, and then produces the actioncommand information S16 depending on the parameters for the action,followed by transmitting it to the posture transition mechanism 42.

Additionally, the input information S1-S3 given by the command signalsS1, the external information signals S2 and the internal informationsignals S3 are applied to both the emotion/instinct model unit 40 andthe action deciding mechanism 41 because the contents of the inputinformation are different depending on the timing at which those signalsare applied to the emotion/instinct model unit 40 and the actiondeciding mechanism 41.

For example, when the external information signals S2 indicating “theuser strokes the head” are supplied, the controller 32 causes theemotion/instinct model unit 40 to produce the emotion/instinct stateinformation S10 indicating “delight”, and then supplies the producedemotion/instinct state information S10 to the action deciding mechanism41. At this moment, if the external information signals S2 indicating“there is the user's hand just under the robot nose” are supplied, thecontroller 32 causes the action deciding mechanism 41 to produce theaction command information S16 instructing “the pet robot gives the handwith joy”, based on both the emotion/instinct state information S10indicating “delight” and the external information signals S2 indicating“there is the user's hand just under the robot nose”, followed bytransmitting the action command information S16 to the posturetransition mechanism 42.

Returning to FIG. 3 again, the posture transition mechanism 42 producesposture transition information S18 for transition from the currentposture to the next posture based on the action command information S16supplied from the action deciding mechanism 41, and then transmits theposture transition information S18 to the control mechanism 43. On thatoccasion, the next posture capable of being transited from the currentstate is decided depending on physical features of the pet robot 1 suchas the shapes and weights of the body, hands and legs, including jointmanners between them, and on mechanisms of the actuators 24A-23N such asthe directions and angles in and over which the articulations arebendable.

Here, the transition-enable postures are grouped into postures capableof being directly transited from the current state and posturesincapable of being directly transited from the current state. Forexample, the four-footed pet robot 1 can directly transit from theposture lying sprawled to the posture lying down, but cannot directlytransit from the posture lying sprawled to the stand-up posture. Thelatter transition requires two-step motions, i.e., a first step ofdrawing the hands and legs near the body to take the posture lying down,and a second step of standing up from the posture lying down. Also,there are postures which the pet robot cannot take with safety. Forexample, the four-footed pet robot 1 turns over easily when attemptingto raise both the hands for cheering from the stand-up posture.

In view of the above, the postures capable of being directly transitedare registered beforehand in the posture transition mechanism 42. Whenthe action command information S16 supplied from the action decidingmechanism 41 indicates the posture capable of being directly transited,the posture transition mechanism 42 transmits that action commandinformation S16, as the posture transition information S18, to thecontrol mechanism 43. On the other hand, when the action commandinformation S16 supplied from the action deciding mechanism 41 indicatesthe posture incapable of being directly transited, the posturetransition mechanism 42 produces the posture transition information S18for effecting transition to the target posture after transition toanother posture capable of being directly transited, and then transmitsthe produced posture transition information S18 to the control mechanism43. By employing such two-step motions, the pet robot 1 is avoided frombeing forced to take the posture incapable of being transited, or fromturning over because of posture transition beyond its ability.

Concretely, in the posture transition mechanism 42, the postures capableof being taken by the pet robot 1 are registered beforehand, and therelations between every two postures capable of being transited from oneto the other are recorded. As shown in FIG. 8, for example, the posturetransition mechanism 42 employs an algorithm called a directional graph60 in which the postures capable of being taken by the pet robot 1 arerepresented by nodes ND1-ND5, and every two postures capable of beingtransited from one to the other among the nodes ND1-ND5 are coupled bydirectional arcs a1-a10.

When the action command information S16 is supplied from the actiondeciding mechanism 41, the posture transition mechanism 42 plans such aposture transition schedule that the node ND corresponding to thecurrent posture is coupled to the node ND which is represented by theaction command information S16 and corresponds to the posture to betaken next, by searching a route leading from the current node ND to thenext node ND following the direction indicated by each directional arca, and by recording the nodes ND positioned on the searched route inorder. As a result, the pet robot 1 can realize the action instructed bythe action deciding mechanism 41 while it is avoided from being forcedto take the posture incapable of being transited, or from turning overbecause of posture transition beyond its ability.

Assuming now, for example, that the current posture corresponds to thenode ND2 indicating the “lying-down” posture, when the action commandinformation S16 indicating “sit down” is supplied, the posturetransition mechanism 42 supplies the posture transition information S18indicating “sit down” to the control mechanism 43 upon determining thatit is allowed to directly transit from the node ND2 indicating the“lying-down” posture to the node ND5 indicating the “sitting” posture.On the other hand, when the action command information S16 indicating“walk” is supplied, the posture transition mechanism 42 plans a posturetransition schedule by searching a route leading from the node ND2indicating the “lying-down” posture to the node ND4 indicating the“walking” posture, and then produces the posture transition informationS18 first instructing “stand up” and thereafter instructing “walk”,followed by transmitting the produced posture transition information S18to the control mechanism 43.

Returning to FIG. 3 again, the control mechanism 43 produces the controlsignals S5 for driving the actuators 23 based on the posture transitioninformation S18, and then transmits the produced control signals S5 tothe actuators 23. The actuators 23 are thereby driven to operate the petrobot 1 in a desired manner.

(4) Operation and Advantages

In the above construction, the emotion/instinct model unit 40 in thecontroller 32 changes the emotional and instinctive states of the petrobot 1 based on the input information S1-S3 supplied thereto, so thatsuch changes of the emotional and instinctive states are reflected uponthe action of the pet robot 1. This enables the pet robot 1 toautonomously behave in accordance with the emotional and instinctivestates created in itself.

The action deciding mechanism 41 in the controller 32 decides the nextState subsequent to the current State based on both the current Statedepending on a history of the input information S14 having been suppliedin succession and the input information S14 supplied next. This alsocontributes to enabling the pet robot 1 to autonomously behave inaccordance with the emotional and instinctive states created in itself.

The posture transition mechanism 42 in the controller 32 changes thecurrent posture of the pet robot 1 for transition from the currentposture to the posture corresponding to the action command informationS16 via a predetermined route. The pet robot 1 is thereby avoided frombeing forced to take an impossible posture or from turning over.

With the above construction, the emotional and instinctive states of thepet robot 1 are changed based on the input information S1-S3 supplied tothe controller 32, and the action of the pet robot 1 is decided based onsuch changes of the emotional and instinctive states. The posturecapable of being transited is selected depending on the decided actionto operate the pet robot 1 so that it autonomously behaves in accordancewith the emotional and instinctive states created in itself. As aresult, the pet robot 1 behaving very like a genuine pet can berealized.

(5) Other Embodiments

While the above embodiment has been described in connection with thecase of receiving the user's commands transmitted from the remotecontroller in the form of infrared rays, the present invention is notlimited to that case. For example, the user's commands may betransmitted in the form of electrical waves or sound waves.

Also, while the above embodiment has been described in connection withthe case of receiving the user's commands via the command receiving unit30 made up of the remote-controller command receiver 13 and themicrophone 11, the present invention is not limited to that case. Forexample, a computer may be connected to the pet robot 1 and the user'scommands may be received via the connected computer.

Furthermore, while the above embodiment has been described in connectionwith the case of deciding the emotional and instinctive states using theemotion units 50A-50C indicating three kinds of emotions, i.e.,“delight”, “grief” and “anger”, and the desire units 51A-51C indicatingthree kinds of desires, i.e., “appetite”, “sleepiness” and a “desire forexercise”, the present invention is not limited to that case. Forexample, an emotion unit indicating “loneliness” may be added to theemotion units 50A-50C, or a desire units indicating a “desire foraffection” may be added to the desire units 51A-51C. Stated otherwise,the emotional and instinctive states may be decided by a combinationincluding other various kinds of emotion units and desire units in anyother suitable number than described above.

While the above embodiment has been described in connection with thecase of deciding the next action by the action deciding mechanism 41based on the command signals S1, the external information signals S2,the internal information signals S3, the emotion/instinct stateinformation S10, and the behavior information S12, the present inventionis not limited to that case. The next action may be decided based on apart of the command signals S1, the external information signals S2, theinternal information signals S3, the emotion/instinct state informationS10, and the behavior information S12.

While the above embodiment has been described in connection with thecase of deciding the next action by employing an algorithm called thefinite automaton 57, the present invention is not limited to that case.The next action may be decided by employing an algorithm called a Statemachine in which the number of States is not finite. In that case, a newState is produced each time the input information 14 is supplied, andthe next action is decided depending on the produced State.

While the above embodiment has been described in connection with thecase of deciding the next action by employing an algorithm called thefinite automaton 57, the present invention is not limited to that case.The next action may be decided by employing an algorithm called aprobability finite automaton in which a plurality of States are selectedas candidates for the destination of transition based on both the inputinformation S14 currently supplied and the State at that time, and adesired one of the plurality of States selected as the destinationcandidates is decided at random by using random numbers.

Moreover, the above embodiment has been described in connection with thecase that when the action command information S16 indicates the posturecapable of being directly transited, that action command information S16is transmitted, as the posture transition information S18, to thecontrol mechanism 43, but when the action command information S16indicates the posture incapable of being directly transited, the posturetransition information S18 for effecting transition to the targetposture after transition to another posture capable of being directlytransited is produced and transmitted to the control mechanism 43.However, the present invention is not limited to that case. As analternative, only when the action command information S16 indicates theposture capable of being directly transited, that action commandinformation S16 may be accepted and transmitted to the control mechanism43, but when the action command information S16 indicates the postureincapable of being directly transited, that action command informationS16 may be rejected.

Additionally, while the above embodiment has been described inconnection with the case of applying the present invention to the petrobot 1, the present invention is not limited to that case. For example,the present invention is also applicable to other various robotapparatuses such as those robot apparatuses which are employed in thefields of games and exhibitions for the purpose of entertainment.

According to the present invention, as described above, since a robotapparatus includes emotion/instinct models linked to an action anddecides the next action by changing the emotion/instinct models based onthe input information, the robot apparatus can autonomously behave inaccordance with the emotional and instinctive states created in itself.As a result, a robot apparatus autonomously behaving in a natural waycan be realized.

Since the next operating state subsequent to the current operating stateis decided based on both the current operating state depending on ahistory of the input information having been supplied in succession andthe input information supplied next, the robot apparatus canautonomously behave in accordance with the emotional and instinctivestates created in itself. As a result, a robot apparatus autonomouslybehaving in a natural way can be realized.

Since the current posture of the robot apparatus is changed fortransition from the current posture to the posture corresponding to theinput information via a predetermined route, the robot apparatus can beavoided from being forced to take an impossible posture or from turningover. As a result, a robot apparatus autonomously behaving in a naturalway can be realized.

What is claimed is:
 1. A robot apparatus comprising: a portion; controlmeans for controlling said portion; and a posture transition modelincluding states of a posture between which transition is allowed;wherein said control means controls said portion based upon said posturetransition model in order to have said robot generate behavior orperform actions.
 2. The robot apparatus according to claim 1, whereinsaid posture transition model comprises a first node indicative of afirst posture of said robot apparatus, a second node indicative of asecond posture of said robot apparatus, and an arc indicative of capabletransitioning directly from said first node to said second node.
 3. Therobot apparatus according to claim 1, wherein said posture transitionmodel transits postures by employing a directional graph in which aplurality of nodes representing postures capable of being taken by saidrobot apparatus are registered beforehand, and every two among thepostures capable of being directly transited from one to the other arecoupled by a directional arc.
 4. The robot apparatus according to claim1, wherein said posture transition model plans a posture transitionschedule by searching a route from a node corresponding to the currentposture to a next node while following a direction indicated by eachrespective directional arc.
 5. A robot apparatus comprising: a sensoroperable to detect an input signal supplied to said robot apparatus fromat least one of an external stimulus and an internal stimulus; means fordetermining at least one semantic content in accordance with thedetected input signal; an instinct model for generating at least oneparameter defining a predetermined instinct; changing means for changingat least one instinct parameter based upon the semantic content; and abehavior model for deciding a next action or behavior based upon atleast one of a current state and a last state; wherein said behaviormodel decides an action or behavior in accordance with the instinctparameter, and said changing means changes said at least one instinctparameter based upon said decided action or behavior.
 6. A robotapparatus comprising: a sensor operable to detect an input signalsupplied to said robot apparatus from at least one of an externalstimulus and an internal stimulus; means for determining at least onesemantic content in accordance with the detected input signal; anemotion model for generating at least one parameter defining apredetermined emotion; changing means for changing at least one emotionparameter based upon the semantic content; and a behavior model fordeciding a next action or behavior based upon at least one of a currentstate and a last state; wherein said behavior model decides an action orbehavior in accordance with the emotion parameter, and said changingmeans changes said at least one emotion parameter based upon saiddecided action or behavior.
 7. A robot apparatus comprising: a portion;control means for controlling said portion; a posture transition modelincluding states of a posture between which transition is allowed; asensor operable to detect an input signal supplied to said robotapparatus from at least one of an external stimulus and an internalstimulus; means for determining at least one semantic content inaccordance with the detected input signal; an instinct model forgenerating at least one parameter defining a predetermined instinct;instinct changing means for changing at least one instinct parameterbased upon the semantic content; a behavior model for deciding a nextaction or behavior based upon at least one of a current state and a laststate; an emotion model for generating at least one parameter defining apredetermined emotion; and emotion changing means for changing at leastone emotion parameter based upon the semantic content; wherein saidcontrol means controls said portion based upon said posture transitionmodel in order to have said robot generate behavior or perform actions;and wherein said behavior model decides an action or behavior inaccordance with at least one of the instinct parameter and the emotionparameter, and said instinct changing means changes said at least oneinstinct parameter and said emotion changing means changes said at leastone emotion parameter based upon said decided action or behavior.